WO2021032532A1 - Device for producing book covers, box lids or game boards - Google Patents

Abstract

The invention relates to a device for producing book covers, box lids or game boards, comprising a cutting device, which is arranged in the region of the panel feed, for knocking off the panel edges, wherein each tool pair of cutting cylinder and counter-pressure cylinder is held in a common bearing block and the bearing arrangement of the cutting cylinder comprises two mutually spaced eccentric bushes and a drive element arranged between the eccentric bushes.

Description

Device for the production of book covers, box covers or

Game boards

The present invention relates to a device according to the preamble of claim 1

A book cover machine with a horizontal processing principle is known from DE102010024232A1, which combines cardboard cover and a back insert made of cardboard or cardboard so as to fit with the cover panels provided with adhesive in a rolling device. The protruding edges of the book cover are then tucked into one behind the other in workstations either in a flowing cycle or at a standstill. Left and right corner repelling devices are arranged along the panel feed, with which corner sections with a predetermined repelling width at the leading and trailing edge are separated from the reference panels as the reference panels pass through. The rotary tools of the corner push-off devices are driven by a servomotor, which enables the push-off width to be set electronically in accordance with the respective height and opened width of the book covers.

On the one hand, the corner sections should be completely separated from the reference panel in order to obtain a clean cut. On the other hand, tool wear should be kept as low as possible. For this it is necessary to set the center distance between the cutting cylinder and the impression cylinder very precisely. They are there too

Material properties of the reference panel and the respective condition of the knife and impression cylinder must be taken into account.

Circular shears for longitudinal cutting of webs are known from DE4125508A1. Knife and counter knife are each attached to a shaft end. There is a on the opposite end of the shaft Drive element provided. The storage of the shafts is arranged between the knife and the drive element. It comprises several rolling bearings received in a common socket. The socket is eccentric and rotatably mounted in a frame. The rotary position of this socket in the frame determines the center distance of the knives in the circular shears.

Radial loads acting on the shaft ends lead to elastic deformation of the shafts. In addition to the restoring forces caused by the cutting, radial forces also have to be borne by the knife drive. Even if the resulting unintentional changes in the center distance in the area of cutting are very small, the influence on the cutting quality is considerable in many cases. In particular, an angle error resulting from the bending leads to unsatisfactory cutting quality in the case of drum knives of corner repelling devices.

The proposed arrangement allows only a parallel displacement of the axes of rotation within a tool and does not provide any possibility of avoiding or at least compensating for the elastic deformation of the cutter shafts.

It is therefore an object of the present invention to create a device which is improved over the prior art and which overcomes at least one of the indicated disadvantages of the prior art and satisfies the increased demands on the product quality to be achieved.

The invention solves the problem by a device with the features of claim 1. Advantageous further developments of the invention are characterized by the features specified in the subclaims.

A device according to the invention is used to produce book covers, box covers or game boards from at least one cardboard blank, which is covered with at least one common reference panel. At least one area of the reference panel that protrudes from the cardboard is wrapped around a cardboard edge on the back. For this purpose, the device comprises a joining device which positions the cardboard and the associated blank blanks with respect to one another and glues them at least in certain areas.

The cardboard elements that jointly form a product are fed synchronously to the joining device by a cardboard feed located in the product flow of the joining device. For this purpose, the cardboard feed has at least one transport path. The cardboard supply can also comprise one or more cardboard magazines with corresponding separation devices.

The reference panels are fed to the joining device by a transport path of the panel supply in each case to match the cardboard. Upstream of the sheet transport route, the sheet feed includes a separation device. This separating device separates one copy sheet from a supply such as a stack of sheets.

An adhesive application device is arranged on the panel transport path. This divides the feed into a first section upstream of the adhesive application and a second transport section downstream of the adhesive application. This second section is followed by the joining device as seen in the product flow. The adhesive application device is arranged such that it applies adhesive to the adhesive side of the blank during the transport movement of the reference blank.

Following the joining device, at least one wrapping device of a known type is arranged, which knocks overhangs of the cover panels onto the back of the cardboard.

The device has a cutting device with at least one pair of tools in the area of the first section of the panel transport upstream of the adhesive application device. The tool pair penetrates the Transport level of the corresponding transport section of the panel supply. It is made up of a cutting cylinder and an opposing cylinder.

At least the cutting cylinder has a cutting edge that is raised with respect to an outer cylinder surface. The counter cylinder can be designed as an impression cylinder without a cutting edge or also as a cutting cylinder. Both tools in a pair can each be rotated around an axis. The axes of rotation of a pair are aligned essentially parallel to one another and essentially perpendicular to the transport direction of the reference pieces. The cutting cylinder and the counter cylinder of a pair are drivingly connected to one another.

The tool pair is arranged in a common bearing block. The storage of at least one of the tools in the common bearing block comprises at least two eccentric sockets. The rotary position of the two sockets in the bearing block determines the center distance of the tools in a pair. The two eccentric sockets of the tool are arranged on the same side of the respective tool. In this way, opposite tool pairs can be arranged on both sides of the transport path, whereby a compact design of the device is possible.

The two sockets of a tool are spaced apart from one another in the axial direction. A drive element of the drive connection of the two tools of a pair is attached between them. This arrangement leads to a rigid tool storage. In addition, the arrangement of the drive connection between the bearing points, especially when using spur gears as a drive connection under drive load, reduces the center distance in the area of the cutting edge. This counteracts the expansion caused by the cutting forces.

In an advantageous embodiment, at least one of the eccentric bushes is drive-connected to a feed device, so that the rotary position of the eccentric bush is determined by the feed device. So the Center distance within a tool pair can be set in a simple and repeatable manner.

This infeed device preferably has a display element which makes available information that can be interpreted as an axis distance. A desired center distance can thus be set particularly easily.

In order to prevent unwanted adjustment of the center distance, especially during operation, the eccentric bushings can be locked in their rotational position. For this purpose, the feed device preferably has a self-locking gear. A worm drive, which enables a very compact design of the feed device, is particularly advantageous.

The delivery device advantageously comprises a controllable drive which is connected to the controller of the device by means of a data connection. This enables automated adjustment of the center distance. Previously saved settings can be reproduced easily and, if necessary, without the intervention of operating personnel.

The eccentric sockets of a tool are preferably decoupled from one another with regard to their rotational positions so that they can be adjusted individually. In this way, a parallel deviation of the axes of rotation of a tool pair can be set in a targeted manner. A setting in which the axes of rotation approach one another from the side of the tool facing the bearing to the side of the tool facing away from the bearing is particularly advantageous. Thus, the tools of a pair can be clamped to one another in such a way that an undesired non-uniform widening of the center distance over the tool width caused by the cutting forces is compensated for. With a separate feed device assigned to each eccentric bush, this bias of the tool pair can also be set in a simple manner in addition to the distance. The cutting device advantageously comprises at least one sensor which determines a value which can be interpreted as a force acting radially on the tool. This sensor is preferably connected to the control of the device by means of a data line. In this way the radial cutting force can be determined. Their increase can indicate wear on the tool. Corresponding information can be displayed to the operating personnel. In addition, in conjunction with the controllable infeed device, it is also possible to regulate the radial force acting on the tool. In this way, the required cutting forces can be specified depending on the material.

In an advantageous embodiment, the at least one pair of tools can be positioned essentially transversely to the transport direction of the reference panels. In this way, different formats or cutting positions can be created with one pair of tools. The cutting device preferably has a parking or maintenance position for the pair of tools outside of the panel transport path. This makes it possible to disengage the tools without changing the center distance. This enables a lower eccentricity of the bushes and a more precise setting of the center distance. In the same way, an additional device for opening the pair of tools can be dispensed with and a compact and rigid construction can be made possible.

A simple transport device guides the finished book covers, box covers or game boards out of the device and makes them available for further processing.

The invention will then be explained with reference to the figures, to which reference is made with regard to all details not mentioned in more detail in the description, using exemplary embodiments. The figures show:

1 shows a schematic side view of a book cover machine;

2 is a perspective view of a cutting device for pushing off utility corners of a page; 3 shows a schematic view of a cutting device for pushing off utility corners of a page;

FIG. 4 shows a sectional view according to the view definition in FIG. 1.

As shown in FIG. 1, an exemplary blanket machine comprises a cardboard feed 1 with a cardboard feed direction g, a blank feed 2 with a blank feed direction b, a blanket outlet 6 and several processing stations 4, 5, 7, 9. The processing stations 4, 5, 7, 9 are in the direction of the product flow, each along the panel feed 2 or between the cardboard feed 1, the panel feed 2 and the ceiling outlet 6.

Downstream of the blank feed 2 there is an adhesive application device 4. Its blank cylinder takes over the blank 105 provided by the blank feed 2 and guides it along an application roller into the joining device 5. The application roller transfers the adhesive to the blank 105 possible by one or more application nozzles not shown in the figures.

In the joining device 5, the blank 105 provided with adhesive is rolled onto one or more cardboard blanks 101. For this purpose, the joining device 5 provides a stationary joining roller that rolls on the utility cylinder. The one or more cardboard blanks 101 are provided to the joining device 5 by the cardboard supply 1.

In the direction of the product flow downstream of the joining device 5, several wrapping devices 7 are arranged. These knock-in devices 7 each have several knock-in elements. The wrapping elements capture the protrusions of the panel blanks 105 with respect to the joined cardboard blanks 101 and fold them around the outer edges of the cardboard blanks 101 up to the inside of the ceiling and press them on.

The outlet 6 is arranged downstream of the knock-in devices 7. She takes over the finished blankets, stacks them, guides these blanket stacks across the Use or cardboard transport direction b, g from the ceiling machine and provides them there.

According to FIG. 4, a cutting device 9 is arranged in the region of the sheet feed 2 for cutting the reference sheet 105 from the separated sheet 102. A first unit consists of circular shears 32. As a longitudinal cutting device, these are arranged to penetrate the panel transport plane B with their axes of rotation transverse to the panel transport direction b. A controllable feed drive 30 enables the circular shears 32 to be positioned transversely to the panel transport direction b. In this way, panels of different widths can be created from the same raw formats. The lateral section is removed from the reference panel 105 and carried away by guide elements of a known type (not shown).

Following in the panel transport direction b of the circular shears, two cutting units shown in FIG. 2 are arranged on both sides of the panel transport path. These two cutting units serve to push off the corners 104 of the multi-copy sheets 102. They are constructed in mirror images of one another. Each comprises a pair of tools 10 comprising a cutting cylinder 11 and an impression cylinder 12. Each of these two cutting units, like the circular shears 32, can be positioned transversely to the panel transport direction b according to the reference panel width.

The cutting cylinder 11 arranged above the blank transport plane B is cylindrical with a hard cutting edge 24 raised in relation to the lateral surface 23. This cutting edge 24 is designed in a spiral shape such that its development on the blank transport plane B forms a diagonal cut.

In contrast, the associated impression cylinder 12 is cylindrical with a smooth surface made of a softer material. The end faces of cutting cylinder 11 and impression cylinder 12 of the same pair of tools 10 are aligned with one another. Both cylinders 11, 12 are accommodated in a common bearing block 13 by means of roller bearings 34. Your axes of rotation 16, 17 are aligned parallel to each other and transversely to the panel transport direction b. The axes of rotation 16, 17 jointly define the tool plane C.

The cutting cylinder 11 is drive-connected to a servomotor 27 by a belt drive. A gear 14 made up of spur gears 15 represents the drive connection between the cutting cylinder 11 and the impression cylinder.

Each of the roller bearings 34 assigned to the cutting cylinder 11 is received in an eccentric bush 18. These are rotatably arranged in the bearing block 13. The rotational position of the bushings 18, together with their eccentricity e, determines the center distance a between the cutting cylinder 11 on the one hand and the impression cylinder 12 on the other. A small amount of eccentricity e allows a very precise setting of the tool pair 10.

For convenient operation, each eccentric bushing 18 is assigned a feed device 19. The use of a spindle drive 20 with a sufficiently small pitch allows, on the one hand, very precise adjustment and, on the other hand, leads to self-locking, so that unintentional adjustment during operation is avoided. Alternatively, a controllable feed device 19 with a spur gear is shown in FIG. 3. Of course, the controllable drive 22 from FIG. 3 can be supplemented in a delivery device according to FIG. 2, so that automated setting is possible in both cases.

The use of a feed device 19 for each eccentric bushing 18 makes it possible to adjust the axes of rotation 16, 17 of the tools 11, 12 to one another in a targeted manner. 3 shows a setting with an outer axis distance aa of the shaft end facing away from the cutting cylinder 11 and an inner axis distance ai at the free end face of the cutting cylinder 11. The outer axis distance aa is greater than the inner axis distance ai due to the selected rotational positions of the eccentric bushings 18. If the sheet 102 passes through the tool pair 10, it expands the inner center distance ai due to elasticities and leads to a slight bending of the axis of rotation. A suitable uneven adjustment of the eccentric bushings can compensate for this bending. This inclination in the unloaded state is shown exaggerated in Fig. 3 for reasons of clarity.

The spur gears 15 of the drive connection 14 of the cutting cylinder 11 and the impression cylinder 12 are each arranged between the eccentric bushings 18. The radial forces generated by the drive lead in the area of the drive connection 14 to an increase in the center distance due to bending. The inner center distance ai, however, is reduced. This arrangement, together with the preset inclination according to FIG. 3, compensates for the increase in the inner center distance ai resulting from the cutting forces, so that the center distance in the region of the cutting edge 24 is constant.

All controllable drives 22, 27, 30 are connected to the controller 25 of the device by data lines. A data memory 26 is assigned to the machine control 25, so that any stored production orders can be called up and the associated machine settings, such as, for example, the position of the tool pairs 10, can be set automatically.

Claims

Claims

1. Device for the production of book covers (103), box covers or

Game boards, at least having a first feed device (1) for cardboard blanks (101) with a first

Transport direction (g), in which the cardboard blanks (101) are fed,

• a second feed device (2) for reference panels (102, 105) with at least

• a second transport direction (b), in which the reference copies (102, 105) are fed,

• a separation device (3) for reference items (102, 105) and

• one in the second transport direction (b) of the reference panels (102, 105) of the separating device (3) for reference panels (102, 105) downstream cutting device (9), one in the second transport direction (b) of the reference panels (102, 105) adhesive application device (4) downstream of the second feed device (2) for reference panels (102, 105),

• a joining device (5) downstream in the material flow of both the first feed device (1) for cardboard blanks (101) and the adhesive application device (4),

• an execution device (6) arranged downstream in the material flow of the joining device (5) for cardboard blanks (101) with reference panels (105), as well as

• a cutting device (9) arranged in the area of the second feed device (2) for reference panels (102, 105) with at least

A pair of tools (10) which penetrates the transport plane (B) of the reference utility (102, 105) and consists of a rotatable cutting cylinder (11) with an outer surface (23) and at least one cutting edge (24) and a raised edge relative to the outer surface (23) the rotatable impression cylinder (12) associated with the at least one cutting cylinder (11), the first axis of rotation (16) of the cutting cylinder (11) and the second axis of rotation (17) of the impression cylinder (12) of the same at least one pair of tools (10) are arranged essentially parallel to one another and together essentially transversely to the second transport direction (b) of the reference pieces (102, 105),

• a tool holder with at least one bearing block (13) in which the cutting cylinder (11) and the impression cylinder (12) of the same at least one pair of tools (10) are accommodated,

• a drive connection (14) of the impression cylinder (12) with the cutting cylinder (11) of the same at least one pair of tools (10),

• a variable center distance (a, aa, ai) of the first axis of rotation (16) of the cutting cylinder (11) to the second axis of rotation (17) of the impression cylinder (12) of the same tool pair (10),

• two sockets (18) of the tool holder each with a bore (28) in which either the at least one cutting cylinder (11) or the at least one counter-pressure cylinder (12) is received and with at least one further lateral surface (29) and

• one-sided mounting of the cylinders (11, 12) in the bearing block (13) of the at least one tool pair (10), with the at least two bushes (18) of the same tool (11, 12) on the same side of this tool (11, 12) are arranged, characterized in that

• in each case the bore (28) of the bush (18) is arranged eccentrically to the at least one further jacket surface (29) of the same bush (18),

• the at least two bushes (18) each with their at least one further outer surface (29) are rotatably received in the at least one bearing block (13) in such a way that a change in the rotational position of the bush (18) changes the position of the axis of rotation (16 , 17) of the cutting cylinder (11) or counter-pressure cylinder (12) accommodated in the bushing (18),

• the at least two sockets (18) assigned to the same cylinder (11, 12) of a tool pair (10) are spaced apart (h) in the axial direction and • at least one drive element (15) of the drive connection (14) of the impression cylinder (12) with the cutting cylinder (11) of the same at least one tool pair (10) is arranged between the at least two bushings (18) assigned to this tool pair (10).

2. Device according to claim 1, characterized by at least one with at least one of the at least two sockets (18) rotatably connected delivery device (19).

3. Apparatus according to claim 2, characterized by at least one display element (21) of the at least one feed device (19), which is at least one as a distance (a, aa, ai) of the axes of rotation (16, 17) of the cutting cylinder (11) and this associated impression cylinder (12) provides interpretable information in a plane (C) defined by the bushing (18) associated with the delivery device (19).

4. Apparatus according to claim 2 or 3, characterized by at least one screw drive (20) of the at least one feed device (19) which acts on the respectively assigned bushing (18).

5. The device according to at least one of claims 2 to 4, characterized by at least one controllable drive (22) of the at least one delivery device (19) and at least one data connection between the at least one controllable drive (22) and a controller (25) of the device.

6. Device according to at least one of the preceding claims, characterized in that the rotational positions of the at least two sockets (18) of the same tool (11, 12) are individually adjustable.

7. Device according to at least one of the preceding claims, characterized by an inner center distance (ai) of the cylinders (11, 12) of the at least one tool pair (10) and an outer center distance (aa) of the cylinders (11, 12) of the same tool pair (10) ), whereby in the unloaded state of the tool pair (10) the inner center distance (ai) is slightly smaller than the outer center distance (aa) of the same tool pair (10).

8. Device according to at least one of the preceding claims, characterized by at least one transducer (33) of the at least one cutting device (9) which detects a value that can be interpreted as a force acting radially on at least one cutting tool (11, 12) and at least one data connection of the transducer (33) with the control (25) of the device.

9. Device according to at least one of the preceding claims, characterized in that the at least one bearing block (13) with the at least one pair of tools (10) can be positioned essentially transversely to the feed direction (b) of the reference utility (102, 105).

10. The device according to claim 9, characterized by at least one maintenance position (31) of the at least one tool pair (10) outside the transport path of the reference utility (102, 105) that the at least one tool pair (10) positioned in its maintenance position (31) does not have any Has an effect on a reference utility (102, 105) moved by the cutting device (9).